Method and apparatus for adjusting power consumption during server operation

ABSTRACT

A method for adjusting power consumption during server operation is disclosed. The method comprises initializing the server to a system power performance state (SPP-state) that comprises a plurality of constituent power settings, determining whether power regulation is required while the server is operating at the current SPP-state, setting a flag if power regulation is required, and increasing at least one of the plurality of constituent power settings associated with the SPP-state if the flag has been set.

BACKGROUND

Computers are ubiquitous in society. For example, computers are presentin everything from user-oriented desktop computer systems to complexnetworks of computers that facilitate credit card transactions. Thesecomplex networks represent a trend toward consolidating computers toimplement high-density computing configurations, which are sometimesreferred to as “data centers.” In fact, it is not uncommon for thesedata centers to include tens of thousands of servers or more. To supportof these data centers, information technology (IT) professionals havehad to shoulder new burdens that were previously not of concern to ITprofessionals: power consumption and temperature maintenance.

Previously, data center facilities managers were primarily responsiblefor providing the specified power to the computers within the datacenter and were also responsible for maintaining the ambient airconditions to match the specified operating conditions of the computerswithin the data center. Typically, power and cooling requirements of thedata center were estimated based on the “name plate” ratings—an estimateof the power and cooling requirements provided by the computermanufacturer. Historically, when computer server power levels were low,this approach proved practical. More recently, however, IT professionalshave begun implementing servers as “blade servers” where each chassis isfilled with multiple server modules, or “blades.” Increasing the densityof the servers in this manner may result in cooling costs for some datacenters (e.g., 30,000 ft²) running into the tens of millions of dollarsper year and also may result in a higher incidence of undesirableservice outages caused by cooling failures.

Some facilities and IT professionals have begun to “de-rate,” or reducethe name plate power and cooling requirements by a fixed amount toincrease the density of servers within a data center. De-rating,however, may still undesirably mis-predict actual power consumption.Other attempts to increase server density include estimating the actualpower consumed with an anticipated application running on the server toprovide a more accurate estimate of the actual power requirements of theserver. However, an unexpected change in computing demand, for exampleas a result of a work load shift between servers, may increase powerdemand and trip a circuit breaker or cause localized over-heating.

BRIEF DESCRIPTION OF THE DRAWINGS

For a detailed description of exemplary embodiments of the invention,reference will now be made to the accompanying drawings in which:

FIG. 1A shows an exemplary data center;

FIGS. 1B and 1C show exemplary floor plans of a data center;

FIG. 2 shows an exemplary computer system;

FIG. 3 shows an exemplary algorithm;

FIG. 4A shows an exemplary server;

FIG. 4B shows an exemplary algorithm;

FIG. 5A shows an exemplary power consumption graph;

FIG. 5B shows another exemplary power consumption graph;

FIG. 5C shows an exemplary algorithm; and

FIG. 6 shows an exemplary algorithm.

NOTATION AND NOMENCLATURE

Certain terms are used throughout the following description and claimsto refer to particular system components. As one skilled in the art willappreciate, computer companies may refer to a component by differentnames. This document does not intend to distinguish between componentsthat differ in name but not function. In the following discussion and inthe claims, the terms “including” and “comprising” are used in anopen-ended fashion, and thus should be interpreted to mean “including,but not limited to . . . .” Also, the term “couple” or “couples” isintended to mean either an indirect or direct electrical connection.Thus, if a first device couples to a second device, that connection maybe through a direct electrical connection, or through an indirectconnection via other devices or connections.

The term “blade server” is intended to refer to a computer system withone of its dimensions, usually the width, substantially smaller than therest. This is usually accomplished by integrating a majority of theserver's components (including processor(s), memory, network cards,etc.) onto the motherboard, allowing multiple blade servers to be rackmounted within a common housing enclosure.

The term “management device” is intended to refer to any device thatpermits remote control functionality such as remote systemconfiguration, remote power control, remote system reset, or remoteoperating system (OS) console of a host computer system.

The term “U” is intended to refer to a standard unit of measure for thevertical space that servers occupy within a server enclosure. Serverenclosures such as racks and cabinet spaces as well as the equipmentthat fit into them are usually measured in U. 1 U is equivalent to about1.75 inches. Thus, a rack designated as 20 U, is a server enclosure thathas 20 rack spaces for equipment and housing enclosures and has 35(20×1.75) inches of vertical usable space.

The term “power-regulation state,” sometimes called “p-states,” isintended to refer to varying levels of power consumption by the CPU,where each level or p-state indicates a different level of CPUfunctionality.

The term “data center” is intended to refer to a group of computers thatperform a computing function. The computers from these data centers areoften, but not always, housed in a common building and may includethousands of computers.

The term “clock modulation” is intended to refer to stopping the clocksignal provided to some or all of the central processing unit (CPU)and/or other portions of a computer that may share this clock. Clockmodulation is often achieved by asserting a STPCLK signal pin of the CPUor its support chipset.

DETAILED DESCRIPTION

The following discussion is directed to various embodiments of theinvention. Although one or more of these embodiments may be preferred,the embodiments disclosed should not be interpreted, or otherwise used,as limiting the scope of the disclosure, including the claims. Inaddition, one skilled in the art will understand that the followingdescription has broad application, and the discussion of any embodimentis meant only to be exemplary of that embodiment, and not intended tointimate that the scope of the disclosure, including the claims, islimited to that embodiment.

Allocating Power within a Data Center

FIG. 1A depicts a data center 100 capable of housing numerous servers(not specifically shown in FIG. 1A). As alluded to in the Background,the thermodynamic limitations and energy availability of data center 100may constrain the number of servers that may be implemented within datacenter 100. Power lines 102 provide power to data center 100 and thispower is consumed by servers within the data center. As power isconsumed by these servers, they generate heat. In order to keep theservers within their recommended operating temperature and preventserver failure, heating ventilation and air conditioning (HVAC) unit 104removes heat generated as a result of server operation from data center100. As is the case with most HVAC systems, even those that includeelaborate water chilled cabinets, there are theoretical limits on theamount of heat that can be removed from the data center 100. Theselimits on the HVAC systems translate into limitations on the amount ofpower per square foot (i.e., power density) that may be consumed byservers within data center 100.

The current theoretical limit of allowable power density is believed tobe about 1000 watts per square foot (W/ft²) including the vacant aislespace between various server enclosures. This theoretical limit of 1000W/ft² assumes that water chilled cabinets are used to house the servers,although some embodiments may implement cooling techniques that yield ahigher theoretical limit. Thus, even if an elaborate cooling system isimplemented, if a server rack and the unoccupied floor space around ittake up 18 square feet (ft²) of floor space, for example, then that rackis theoretically limited to 18,000 watts (W) of power. A typical 1 Userver may consume on the order of 620 W/server, and therefore, themaximum number of servers that may be implemented in this example isapproximately 29, whereas a typical rack may be capable of physicallyaccommodating forty-two 1 U servers. Thus, despite having the floorspace within data center 100 to add more servers to the rack, and theneed to increase computing power by adding more servers to the rack,businesses may be limited from filling the racks to their full capacity.

The embodiments of the present invention may allow for this additionalserver capacity by budgeting the power allocated to “hypothetical”levels within the data center. These hypothetical levels representuser-defined entities that have different power consumptionrequirements. By actively managing the power consumed at each of thesehypothetical levels, the total power consumed by the data center may bekept within a desired budget, thereby allowing more servers to be addedto the data center.

FIGS. 1B and 1C illustrate floor plans of data center 100 according toan embodiment of the present invention. As illustrated in FIG. 1B, datacenter 100 may be divided into various zones (labeled A, B, C, D, and E)that include a plurality of racks 105. The data center 100 may have anoverall power budget based on predefined building specifications, i.e.,power cabling and/or HVAC design. A data center manager 106 may allocatethis overall power budget among zones A-E, for example, according to thepower cabling to a particular zone and/or HVAC capabilities of thatparticular zone. Regardless of the particular allocation method, datacenter manager 106 may allocate the overall power by negotiating withzone managers 107 that are located in each zone. In some embodiments,the data center manager 106 and zone manager 107 may be implemented insoftware, for example, by using the HP Systems Insight Manager (HP SIM)software available from Hewlett-Packard. This software may be executedon the devices illustrated within data center 100. For example, HP SIMmay be used by a data center administrator to define hierarchical levelsof abstraction for zones A-E within data center 100 as well as theprocessing features of data center manager 106 and zone managers 107.

One key feature of zone manager 107 is the ability to adaptively monitorand curtail the power consumption in a zone within the predeterminedamount allocated to it by data center manager 106. For example, if zonemanager 107 monitors physical conditions in zone A and determines thatHVAC unit 104 cannot cool zone A—e.g., because the physical placement ofracks 105 within zone A does not facilitate good airflow—then the zonemanager 107 located in zone A may actively reduce the power budgetassignment of racks 105 within zone A and report this information todata center manager 106.

In a recursive manner, racks 105 also may include a rack manager 108,which may be defined as another hierarchical level of abstraction withinsoftware such as HP SIM. Although rack manager 108 is depicted in FIG.1C as housed in rack 105, in some embodiments, rack manager 108 may be aseparate unit that is not housed in rack 105. Rack manager 108 mayactively manage the amount of power consumed by server enclosures 112.In some embodiments, servers 110 may be implemented with “blade-type”servers, such as the HP ProLiant BL20p server available fromHewlett-Packard.

During operation, rack manager 108 may receive a power budget for itsrack from zone manager 107. In turn, rack manager 108 may divide up thispower budget among server enclosures 112. Likewise, each enclosure 112may include an enclosure manager 111 that is capable of dividing thepower budget for enclosure 112 among the plurality of servers 110 withinenclosure 112. While enclosure manager 111 is shown housed in the sameenclosure 112 as servers 110, other embodiments include housingenclosure manager 111 in other locations. In fact, in some embodiments,enclosure manager 111 may be implemented in software such as HP SIM.

Further still, each server 110 may include a management processor 114that is capable of limiting the amount of power consumed by server 110to be less than or equal to the dynamically assigned budget fromenclosure manager 111. Thus, if zone manager 107 reduces the powerbudget of zone A, then one or more rack managers 108 may further reducethe power budget on one or more enclosure managers 111, which in turnmay reduce the power budget for one or more management processors 114.Note that this adjustment by zone manager 107, rack managers 108, and/orenclosure managers 111 may occur independently and therefore a reductionin the power budget of zone A is not required prior to a reduction ofthe power budget of a particular rack within zone A.

In the end, management processor 114 may react to this reduction inpower budget by limiting the amount of power available to individualcomponents within server 110. Actions that may be taken by server 110 tocurtail its power consumption within the budgeted amount include:slowing down server 110, off-loading work from server 110 and thenshutting it down, not allowing server 110 to be powered up, oroff-loading work such that the server spends more time in the idlestate. For example, management processor 114 may move work load to aserver that consumes less power or is in another zone. Equations 1-4represent the mathematical expressions for the power budgets of thevarious levels of data center 100.

$\begin{matrix}{{DataCenterBudget} \geq {{ZoneA} + {ZoneB} + \ldots + {ZoneZ}}} & {{Eq}.\mspace{14mu} (1)} \\{{ZoneA} \geq {{RackA} + {RackB} + \ldots + {RackZ}}} & {{Eq}.\mspace{14mu} (2)} \\{{RackA} \geq {\sum\limits_{i = 1}^{n}{ServerEnclosure}_{i}}} & {{Eq}.\mspace{14mu} (3)} \\{{ServerEnclosure} \geq {\sum\limits_{i = 1}^{n}{server}_{i}}} & {{Eq}.\mspace{14mu} (4)}\end{matrix}$

Equation 1 illustrates that the sum of the power budgets of each zone isless than or equal to power budget assigned to the entire data center.Equation 2 demonstrates that the sum of the power budgets for each rack(e.g., Rack A through Rack Z) within zone A is less than or equal to thetotal assigned power budget for zone A. Equation 3 illustrates that thesum of the power budgets for each server enclosure within the rack isless than or equal to the total assigned power budget for a rack.Equation 4 demonstrates that the sum of the power budgets of each of theindividual servers is less than or equal to the total assigned powerbudget for the server enclosure. Although four levels of power budgetallocation and control are described in Equations 1-4, in practice,there may be multiple levels of power budget allocation and control(i.e., at least one at each hierarchical level).

Automatic Adjustment of Power Budgets Within a Data Center

As was alluded to above, each server 110 may track (e.g., usingmanagement processor 114) its power budget assignment. In addition totracking its power consumption, however, server 110 also may negotiateto adjust its power budget as its present needs change. This negotiationmay occur between various components within data center 100, such asbetween data center manager 106 and zone managers 107. For example, datacenter manager 106 may direct zone manager 107 in zone B to use anyexcess power reported by zone manager 107 in zone A.

FIG. 2 depicts a block diagram of an exemplary computer server 302capable of negotiating with other components within data center 100 andautomatically adjusting its own power consumption to stay within thenegotiated power budget. Server 302 includes a central processing unit(CPU) 310 that couples to a non-volatile storage device 311 and a bridgelogic device 312 via a system bus (S-BUS).

Non volatile storage 311 is capable of storing executable code and data.The contents of non-volatile storage 311 may be changed from time totime by reprogramming either a portion or the entire non-volatilestorage 311.

Bridge logic device 312 may be referred to as a “North bridge.” In someembodiments, bridge 312 couples to a memory 314 by a memory bus (M-BUS).In other embodiments, however, CPU 310 includes an integrated memorycontroller, and memory 314 connects directly to CPU 310.

Bridge 312 also couples to PCI-Express® slots 318A-B using thePCI-Express® bus standard as disclosed in “PCI-Express BaseSpecification 1.0a,” available from the PCI Special Interest Group(PCI-SIG) and incorporated herein by reference.

As noted above, server 302 may be implemented as a blade-type serverthat is part of a larger data center, such as data center 100.Regardless of the actual implementation of server 302, a managementprocessor 330 may be included in server 302. Management processor 330couples to the various portions of server 302 as well as coupling topower managers for server enclosures 108 as shown. In some embodiments,management processor 330 couples directly to North Bridge 312 via PCI orPCI-Express bus, and in other embodiments, management processor 330couples to North Bridge 312 via a combination of a South Bridge 320 anda PCI-Express bus. Commercial implementations of management processor330 include Hewlett-Packard's Integrated Lights Out (iLO) processor.

During operation, management processor 330 tracks the amount of powerassigned to it by server enclosure 108 (shown if FIG. 1C) as well as thepower consumption needs of server 302. One of ordinary skill in the artwill recognize that of all the components in server 302, CPU 310 is oneof the most power-hungry. Thus, in order to determine whether server 302will benefit from either increasing or decreasing its power budget,management processor 330 monitors several key factors of CPU powerconsumption: CPU utilization and the CPU's power-regulation state.

CPU utilization refers to a measure of how much of a CPU's computingcapacity is being used and indicates the overall activity level of aserver. Fundamentally, CPU utilization may be thought of as thepercentage of time that the CPU spends in a non-idle, active state. Forexample, a CPU that is 100% utilized is executing its maximum possibleworkload.

The CPU's power-regulation state, sometimes termed “p-states,” refers tovarying “states” or levels of power consumption by the CPU, where eachlevel or p-state indicates a different level of CPU functionality. Sincethe CPU is made of numerous transistors that switch on and off toperform desired functions, and each time these transistors switch poweris consumed, the faster the CPU operates the more power it will consume.Accordingly, the different p-states may be accomplished by adjusting theoperating frequency of the CPU. (Note that altering the clockfrequencies to achieve different p-states should not be confused with“clock modulation,” which is described in more detail in subsequentsections of this disclosure.) In addition, to being proportional to theoperating frequency the amount of power consumed by the CPU is alsoproportional to the square of the CPU's operating voltage. In otherwords, the lower the operating voltage, the lower the amount of powerconsumption. Therefore, different p-states may have different operatingfrequencies and different operating voltages.

For example, the P0 p-state is recognized as the highest level ofperformance (and highest possible level of power consumption) since theCPU runs at full operating frequency and full operating voltage in theP0 p-state. Thus, p-states lower than P0, which may be referred to asP1, P2, etc., will include either a lower operating frequency or a loweroperating voltage or both. The precise value of the operating voltageand operating frequency for each p-state is determined by the CPU vendorto optimize CPU utilization while minimizing overall power consumption.Furthermore, each p-state has a target utilization, e.g., P0 may have a100% utilization target while P1 may have a 70% utilization target. Inaccordance with some embodiments, each p-state may be associated with anupper threshold above this utilization and a lower threshold stored innon-volatile storage 311 and these thresholds may be used to adjust thep-state of the CPU as described in more detail below in the context ofFIG. 3.

In any case, management devices, such as management processor 330 orenclosure manager 111, may use p-states to manage the power requirementsof server 302. For example, assume that server 302 is in a p-state otherthan P0 and that CPU utilization is at or near 100%. Further, assumethat according to embodiments of the present invention, server 302 isprevented from raising its p-state (e.g., from a lower p-state to the P0p-state) because of an assignment from an entity further up in thehypothetical levels of data center 100, such as a power state assignmentfrom a server enclosure manager 111. In this scenario where the CPU is100% utilized and its p-state can be raised, server 302 could benefitfrom an increase in its power budget, and therefore may request thatenclosure manager 111 increase its power budget. In a similar fashion,if CPU utilization drops so that the CPU would be less than 100%utilized in the next lower p-state, then server 302 may request thatenclosure manager 111 reduce the power budget assigned to server 302,which in turn may request that rack manager 108 to reassign a powerallocation.

This power budgeting process between the various levels of data center100 continues in a recursive fashion. That is, as enclosure manager 111receives requests for power from the various servers that it manages, ifthe total power requested by these servers exceeds the power budget setby rack manager 108 (i.e., the next level up in the hierarchy of datacenter 100), then enclosure manager 111 will request additional powerfrom rack manager 108.

Since this negotiation process for more or less power budget varies withCPU utilization, and since CPU utilization is unknown prior to bootingup server 302, a baseline power budget may be helpful. Accordingly,prior to powering on server 302, management processor 330 may beprogrammed with the name plate power requirements, and name plate powerrequirements may be used to power on and boot up server 302. Afterpowering on server 302, however, the amount of power for operation maydecrease, and therefore management processor 330 may reassess the powerrequirements of server 302 and adjust accordingly.

FIG. 3 depicts an algorithm 340 that may be implemented by managementprocessor 330 to assess the power requirements of server 302 prior to,during, and after booting up. Beginning in block 350, the maximum powerrating of server 302 may be retrieved from a memory location (such asnon-volatile storage 311) by the management processor 330. In someembodiments, this maximum power rating is the name plate ratingdescribed above.

With the maximum power rating known, management processor 330 then askspermission from the enclosure manager 111 (or other managers higher upthe hierarchical chain) to startup server 302 per block 351. Theenclosure manager 111 then determines whether allowing server 302 tostartup will cause the enclosure manager 111 to exceed its power budgetin block 352. If allowing server 302 to startup will cause enclosuremanager 111 to exceed its power budget, then algorithm 340 may loop backto block 350 and not allow server 302 to startup until either the powerbudget for enclosure manager 111 changes or the maximum powerrequirement for server 302 changes. On the other hand, if allowingserver 302 to startup will not cause enclosure manager 111 to exceed itspower budget, then server 302 is then initialized and a power-on selftest (POST) may be performed in block 355. Note that during execution ofblocks 350-355, management processor 330 is operational despite the factthat server 302 may not be operational.

During boot up, management processor 330 may renegotiate a power budgetthat is less than the name plate rating stored in memory, per block 360.In some embodiments, this negotiation may take place between managementprocessor 360 and other management devices, such as enclosure manager111 and zone manager 107. This negotiation process may include a schemeamong servers that prioritizes the order that servers give power back tothe overall power budget and also prioritizes the order that serverstake power from the overall power budget. For example, some servers maybe executing critical applications and therefore they may be givenhigher priority than servers executing non-critical applications.Further still, the negotiation process may include staging servers suchthat additional servers do not power on and begin negotiating a powerbudget until servers with a higher priority have completed booting upand have reached a stable power budget. This negotiation process alsomay be based on previous history (which may be stored in managementprocessor 330) of servers that have given up and taken back power fromthe power budget in the past.

Once the negotiation is compete, in block 365, management processor 330accounts for the power either provided to or taken from the total powerbudget. Management processor 330 may then report this accounting toenclosure manager 111, or other components higher up in hierarchy.Although the boot process may be complete (in block 370) and control mayhave been passed off to the operating system running on server 302,management processor 330 may dynamically reassess the power requirementsof server 302 by looping through blocks 360 and 365 during serveroperation as is illustrated.

During server operation, management processor 330 may determine (inblock 375) if the current CPU utilization is above or below the upperand lower utilization thresholds for the current p-state. This mayoccur, for example, by checking the contents of non-volatile storage311. If the current CPU utilization is above the upper utilizationthreshold for the current p-state then management processor 330 maydetermine if there is a higher p-state available and may adjust thep-state of CPU 310 accordingly per block 380. At this point, managementprocessor 330 may repeat algorithm 340, including block 365, to accountfor any power increases within the total power budget.

If, however, the current CPU utilization is below the utilization for ap-state, then in block 385, management processor 330 selects a p-state(which may be based on the thresholds stored in non-volatile storage311) whose upper and lower utilization thresholds match the currentserver utilization. Effectively, if a lower p-state is chosen as aresult of block 385 then CPU 310 is relinquishing at least some of thepower allocated to it by management processor 330. Thus, according toblock 360, management processor 330 may negotiate with other managementdevices (e.g., enclosure managers 111 or zone managers 107) todistribute the amount of power relinquished by CPU 310 among the otherdevices under the control of that particular management device. Forexample, if management processor 330 is negotiating with enclosuremanager 111 then other servers within the same enclosure may receive therelinquished power, whereas if management processor 330 is negotiatingwith zone manager 107, then other servers within the same zone mayreceive the relinquished power.

In order to prevent the server that relinquished this power from havingto renegotiate this power back if needed, some embodiments restrictmanagement processor 330 to only negotiate with specific entities in thehypothetical chain, such as with other servers in the same enclosuremanager 111. This may be particularly useful to prevent thrashing—i.e.,where the server relinquishing power goes back and forth between periodsof high activity (i.e., requires more power) to periods of low activity(i.e., requires less power).

In addition to reducing the power consumption of the server by reducingthe power consumption of the CPU, other system components that rely onthe number of requests from CPU (e.g., memory or disk drives) also mayhave their power reduced as a result of reducing the power consumptionof the CPU. For example, during operation, the CPU makes disk accessrequests of the hard drive. Therefore, as the operating frequency of theCPU decreases because of lowering p-states, the number of disk accessrequests also may decrease, and hence, the hard disk may consume lesspower.

Power Budgets Based on Estimated Power Consumption

As mentioned previously, the name plate power may be used as a baselinepower budget upon start up. Note that the name plate power is usually ageneral estimate for each model of server regardless of the server'sconfiguration. In some embodiments, however, an estimated powerconsumption of server 302 may be used as a baseline power budget insteadof the name plate rating. Such a feature may be useful in that serversmay be configured differently (e.g., different number of hard drives)and a power estimate of the actual server being managed may represent amore accurate power budget to begin with.

In order to fully regulate the power consumption of the server, anadditional factor that may be used to control CPU power consumption isthe CPU's “clock modulation,” which is a power control factor that isseparate and apart from CPU p-state and CPU utilization. Clockmodulation is where the clock frequency provided to some or all of theCPU is stopped for a period of time, which substantially reduces powerconsumption to the portions of the CPU that have their clock stopped. Asis evident to one of ordinary skill in the art, the term “STPCLK” is anindustry standard term for the CPU clock modulation control signal.

In some embodiments, the CPU may include a crystal oscillator thatprovides a base frequency to the CPU, and this base frequency may beincreased (possibly by an internal phase locked loop) and then providedto other blocks within the CPU. In these embodiments, clock modulationmay include stopping the clock frequency at the crystal oscillator,stopping the clock frequency at the phase locked loop, or both.Regardless of the actual internal clock distribution within the CPU, theCPU itself may include a STPCLK connection such that when STPCLK isasserted some or all of the internal CPU clock is stopped. Note that thefunctionality of STPCLK may be either active high or active low, andtherefore, “asserting” STPCLK may include coupling a low signal to theSTPCLK connection in some embodiments and in other embodiments it mayinclude coupling a high signal to the STPCLK connection. By controllingthe duty cycle, or percentage of time that a signal coupled to theSTPCLK connection is asserted, power regulation may be achieved throughclock modulation.

This clock modulation, in addition to other server settings may be usedto regulate the power budget, where these settings collectively arereferred to herein as Server Power Performance States or “SPP-states.”That is, SPP-states represent a combination of settings within a serverto effectuate a predetermined amount of power consumption. Theconstituent SPP-state settings include, but are not limited to, CPUp-states, CPU clock modulation or STPCLK settings, as well as variousconfigurations for the server's subsystem components (e.g., the speed atwhich a hard disk drive rotates).

The SPP-state settings for a particular server may be determined priorto deployment and stored in non-volatile storage 311 so that theappropriate STPCLK, p-state, and subsystem settings can be made thatlimit power consumption within the power budget set by the enclosuremanager. For example, server 302 may be outfitted with various availableoptions such as different hard drive types and sizes, memory types andsizes, network cards, and power supplies. In order to measure powerconsumption for each of these unique hardware combinations, maximumcomputational work loads may be run on the server. These maximumworkload tests are deliberately chosen to force server 302 to consume asmuch power as possible. For example, specific software code thatactivates some of the more power hungry portions of CPU 310, like thefloating point unit or arithmetic logic unit, may be run on server 302.During this maximum workload test, the SPP-state settings that result indifferent power consumption levels also may be determined. TheseSPP-state settings that effectuate different power levels are thenstored and this information is made available to hardware or software onserver 302.

Referring again to FIG. 2, management processor 330 may store valuesrepresenting the SPP-state settings for server 302 (based on its uniqueconfiguration) during a maximum work load. While server 302 operates,the SPP-state settings calculated to keep server 302 within the budgetedpower may be selected by setting server 302 to implement actual powerlevels stored in management processor 330 rather than name plate powerlevels. Since the power level achieved using the measured p-state andclock modulation settings reflects the actual power rather than nameplate power, the overall power budget for the data center may beallocated more efficiently.

FIG. 4A depicts a block diagram of an exemplary server 400 capable ofadjusting its power consumption to within the power budget usingSPP-state settings that reflect the unique power consumptionrequirements of server 400. Server 400 includes a power supply 402 thatinterfaces server 400 with the power delivery system of a serverenclosure. Although it is shown as part of server 400, power supply 402may physically reside in other areas of the data center in someembodiments.

Power supply 402 further couples to a power measurement circuit 404.Power measurement circuit 404 measures the power consumption of server400, which may include CPUs 406 and additional system components 408(e.g., memory or hard drives). A comparison circuit 410 couples to powermeasurement circuit 404 as well as coupling to a register 411. Register411 may include a power budget value from a management processor 412(indicated by the dashed line in FIG. 4A) or some other managementdevice. For example, the power budget stored in register 411 also may begiven to it by an enclosure manager 111, or rack manager 108.

The power measurement from measurement circuit 404 is fed to comparisoncircuit 410 and therefore may be referred to as a closed-loop approach.In other embodiments that may be referred to as a more open-loopapproach, comparison circuit 410 may receive a power estimate based onpredetermined lab characterizations instead of real time measurements.In yet other embodiments, a hybrid approach may be used where comparisoncircuit 410 uses the lab characterization at first to start server 400,and then builds a lookup table 414 with the power measurement valuesfrom measurement circuitry 404 as server 400 operates and then uses thisinstead of the lab characterization data.

Regardless of the source of the power consumption, comparison circuit410 may compare this power consumption to the power budget stored inregister 411 and couple the result of this comparison to support logic413. In turn, support logic 413 may control a STPCLK signal that is fedto the one or more CPUs 406 to stop at least some of the clock signalswithin CPUs 406. For example, if the power consumption of server 400 ismuch greater than the power budget value stored in register 411, thenSTPCLK may have a relatively high duty cycle so that the amount of powerconsumed by CPUs 406 is reduced. Likewise, if the power consumption isless than or equal to the value stored in register 411, then STPCLK mayhave a relatively low duty cycle (e.g., 0% stopped) so that the amountof power consumed by CPUs 406 is not restrained by STPCLK. In additionto comparison circuit 410, management processor 412 may adjust otherportions of the SPP-state, such as the p-states of CPUs 406 or theparameters related to the additional system components 408 (e.g., harddrive rotation speed).

FIG. 4B illustrates an exemplary algorithm 415 that may be implementedby server 400 to adjust the SPP-state such that the power consumed byserver 400 is within the power budget. In block 416, managementprocessor 412 receives permission to power on server 400 from anothermanagement device higher up in the hierarchy (e.g., enclosure manager111). Next, in block 418, management processor 412 selects the closestSPP-state that uses less power than the power budget that is assigned toserver 400. The actual implementation of the SPP-state by server 412varies based on whether the closed-loop or open-loop approaches are usedas illustrated in block 419. In the open-loop approach, shown in block420, management processor 412 may effectuate this SPP-state by settingthe CPU STPCLK duty cycle without regard for the output of support logic413. Conversely, in the closed-loop case of block 421, managementprocessor 412 may write the power budget to register 411 and supportlogic 413 may control STPCLK based on comparisons made by comparisoncircuit 410. In both open-loop and closed-loop approaches, however,management processor 412 may set the CPU p-state and the parametersrelated to additional system components 408. Management processor 412then may determine these parameters by consulting the internal lookuptable 414 that reflects the actual power consumption that was producedby running maximum load tests on server 400. Since the value selectedfrom internal lookup table 414 is based on actual work loadrequirements, rather than name plate power estimates, the powernegotiated and subsequently budgeted for server 400 may be moreaccurately estimated. Thus, any over-estimation of power that wouldnormally be present (because of name plate power estimates) may beallocated to other areas of the data center.

Determining Actual Power Dissipation for SPP-states

While the embodiments of the present invention shown in FIGS. 4A and 4Bdepict implementing SPP-states, some embodiments involve determining thevalues of the constituent portions of these SPP-states, such as p-stateand STPCLK settings. These values are optimally chosen to providemaximum computational capability while throttling back power consumptionof the CPU for each SPP-state. Since the actual power consumption is afunction of the potential configurations of the server and theapplications running on the server, however, determining the actualpower dissipation for each SPP-state may be difficult.

FIGS. 5A and 5B depict power consumption curves for the CPUs of twoservers, the DL145 (represented in FIG. 5A) and the DL360 G4(represented in FIG. 5B), both of which are available fromHewlett-Packard, Inc. Referring to FIGS. 5A and 5B, the powerconsumption, in Watts, is depicted on the ordinate axis while theutilization of the CPU is depicted on the abscissa axis (expressed as apercentage). This CPU utilization is determined at the various CPUp-states (where each p-state is represented with a different powerconsumption curve) by varying the work load of the CPU. These powerconsumption curves may be useful in determining desired power regulationvalues for the SPP-states because they represent actual measurements ofthe server being controlled rather than a generalized estimation of aparticular type of server.

As shown in the legend, each curve in FIG. 5A represents a separate CPUp-state for the DL145. For example, FIG. 5A depicts p-states P0-P4,where the line with diamonds represents the P0 p-state, the line withsquares represents the P1 p-state, the line with triangles representsthe P2 p-state, the line with Xs represents the P3 p-state, and the linewith asterisks represents the P4 p-state. Additional p-states arepossible. FIG. 5B includes similar designations for p-states P0-P2 forthe CPU of the DL360 G4.

Referring to FIGS. 5A and 5B, the SPP-states may be represented aspoints along each of the respective p-state curves. For example, withregard to the P0 p-state curve, each point along the curve (representedwith a diamond) may indicate a different level of CPU utilization. Thesedifferent CPU utilization points may also be obtained by running ahigh-utilization work load and asserting different duty cycles forSTPCLK. In other words, the right-most point on the P0 p-state curve,which is marked by SPP0, represents the CPU in the P0 p-state with noSTPCLK signal asserted, i.e., 100% utilized. This SPP0 state correspondsto about 275 W of power consumption. Similarly, the point on the P3p-state curve marked as SPP1 represents the CPU in the P3 p-state withthe CPU capped at about 44% utilization as a result of about a 50% dutycycle on the STPCLK connection. This SPP1 state corresponds to about 175W of power consumption. Various SPP-states may correspond to differentp-state and STPCLK settings, as well as to different settings ofperipheral devices in the system (e.g., hard disk rotation speed).

FIG. 5C illustrates an exemplary algorithm 500 that may be implementedto determine an SPP-state based on actual measurements of the serverbeing controlled. Algorithm 500 also may be used to determine SPP-statesfor other devices within data center 100, such as a network switch.

In block 502, the server is powered on and begins the power on self test(POST) procedure. In general, POST includes code that is executable bythe server and is stored in a storage location, such as non-volatilestorage 311. POST may include initializing the server as well as theserver's peripherals per block 504. Once the initialization is complete,the server then performs a worst case synthetic work load test in block506. During this synthetic work load test, non-volatile storage 311 mayexecute code that reads the actual power consumption as measured bymeasurement circuitry 404 (shown in FIG. 4A). This worst case work loadtest is performed in the SPP0 SPP-state (i.e., P0 p-state and no STPCLK)and then also may be calculated for the remaining SPP-states, ifdesired. Calculating SPP-states rather than only p-states may beadvantageous from a power consumption perspective. Although the variousp-states generally provide the most power savings with the least impacton performance, CPU manufacturers may only define a few p-states so onlyminimal power savings are available by toggling through the variousp-states. Thus, by implementing SPP-states, where the power consumptionis not only dependent on p-states but also may depend on STPCLK settingsor power management of other subsystems, greater power savings ispossible.

The values associated with each of these SPP-states may be entered intolookup table 414 (shown in FIG. 4A), and therefore may be available forlater use during server operation.

Prior to constructing lookup table 414, the overall accuracy ofalgorithm 500 may be set in block 508. If the accuracy of algorithm 500is set high, then the work load test of block 506 may be repeated foreach defined SPP-state per block 510. Once each SPP-state is defined,the server proceeds to booting the operating system in block 516.

On the other hand, if the desired accuracy of algorithm 500 is set low,then algorithm 500 generates fewer points for lookup table 414 andmanagement processor 412 interpolates between these points asillustrated in block 512. For example, in situations where it isunnecessary to calculate the SPP-state with high accuracy, then the codein non-volatile storage 311 may measure the worst case power at SPP0 andalso measure the power consumed by the CPU in the P0 p-state while theCPU is idle, i.e., the minimum power consumption, and then managementprocessor 412 may interpolate between these two by mathematicalinterpolation. With this interpolation complete, in block 514, algorithm500 constructs lookup table 414. With lookup table 414 constructed, theserver proceeds to booting the operating system as illustrated in block516. In some embodiments, these SPP-states may be determined each timethe server is initialized and prior to booting the operating system.

Adjustment of Power Levels During Operation

As discussed above, each server in the data center may be required tolimit its power consumption to within a power budget value assigned by amanagement device higher up in the hierarchy. In the closed-loopembodiments of the present invention, this may be accomplished bychoosing values for the constituent settings of the SPP-states. In theseclosed-loop embodiments, each SPP-state may be associated withconstituent settings such as p-state, STPCLK, and the settings ofadditional system components 408. As discussed above in the context ofFIGS. 5A-C, these constituent settings may be initially chosen prior toserver operation based on actual measurements of the server in question,but are not changed during server operation because of closed-loopoperation. However, since power consumption often depends not only onthe percent utilization of the CPU but the actual sequence ofinstructions being executed, these values that were chosen prior toserver operation using a preselected instruction sequence may need to beadjusted to further optimize power consumption for the user's actualinstruction sequence.

Accordingly, algorithm 600 illustrated in FIG. 6 may further optimizethe power levels associated with these SPP-states during closed loopoperation. Algorithm 600 may be stored in non-volatile storage 311 insome embodiments.

Referring now to FIG. 6, in block 602, the server (such as server 400shown in FIG. 4A) may initialize itself to an SPP-state that representsthe maximum power within a p-state. For example referring back to FIG.5A, this may be the P1 p-state, which consumes about 240 Watts of powerwhen the CPU is 100% utilized. Algorithm 600 then determines whetherthis value represents an optimum value for the user's actual instructionsequence.

While the server is operating at this initial power level, in block 604,it is determined whether power regulation action was required, during aclosed loop operation, to keep server 400 from exceeding the powerbudget established by management processor 412. For example, the user'sactual instruction sequence may consume more power than the preselectedinstruction sequence of the initial SPP-state. If no regulation wasrequired to keep server 400 from exceeding the power budget, then block604 repeats to continually monitor whether regulation action has beenrequired. On the other hand, if power regulation was required to keepserver 400 from exceeding the power budget, then this indicates that theserver's operating conditions have changed such that the closed-loopsettings may not represent the most optimum value, and a flag may be setper block 606. This flag may be implemented in hardware as a bit in aregister of management processor 412 or alternatively this flag may beimplemented in software.

Management processor 412 periodically checks this flag, and if set,increases the power level associated with the current SPP-state perblock 608. This may occur through increasing the constituent settings ofthe SPP-state, such as the p-state. Along with increasing the powerlevel associated with the SPP-state in block 608, management processor412 resets the maximum power measurement of block 602.

Algorithm 600 then determines whether the CPU (such as CPUs 406 shown inFIG. 4A) is over-utilized or under-utilized, per block 610. If the CPUis under-utilized, then algorithm 600 loops back to block 604 to monitorwhether regulation action is required. On the other hand, if the CPU isover-utilized, such as when the CPU is running close to 100%utilization, then algorithm 600 checks the maximum power reading for thecurrent SPP-state per block 612. This maximum power reading may havebeen changed by block 608, or it may have remained the same frominitialization in block 602. If this maximum power reading is less thanthe power at the current SPP-state by a predetermined threshold, thenmanagement processor 412 lowers the SPP-state per block 614. The amountthat management processor 412 lowers the SPP-state by is variable,however, and in some embodiments this amount is set lower than thethreshold value from block 612. Thus, in one embodiment thepredetermined threshold for block 612 is 10%, and the managementprocessor 412 may lower the regulation point power by 5% in block 614.While the SPP-state power is lowered, if the power is lowered to a levelthat is below the lowest p-state, then interpolation may be requiredbetween the measured maximum power for this minimum p-state with nomodulation of the clock and the measured maximum power for this minimump-state with modulation of the clock. Ultimately, in block 616, if theSPP-state changes such that the server is consuming less power, then theserver may allow this power to be reallocated by other managementdevices (e.g., enclosure managers 111 or zone managers 107).

The above discussion is meant to be illustrative of the principles andvarious embodiments of the present invention. Numerous variations andmodifications will become apparent to those skilled in the art once theabove disclosure is fully appreciated. For example, although servers arementioned throughout this disclosure other devices within a data center,such as switches and routers, also fall within the scope of thisdisclosure. In addition, while power thresholds may have been discussedin this disclosure, this disclosure also extends to energy thresholdsthat measure power consumption over time. In this manner, the disclosedembodiments may be regulated according to the amount of heat that theyproduce. It is intended that the following claims be interpreted toembrace all such variations and modifications.

1. A method for adjusting power consumption during server operation, themethod comprising: initializing the server to a system power performancestate (SPP-state) that comprises a plurality of constituent powersettings contained in a table; determining whether power regulation isrequired while the server is executing user applications; and modifyingat least one of the plurality of constituent power settings stored inthe table.
 2. The method of claim 1, wherein the plurality ofconstituent power settings includes a p-state and clock modulation. 3.The method of claim 1, wherein the SPP-state corresponds to a maximumpower consumption threshold of the server.
 4. The method of claim 3,further comprising resetting the maximum power consumption threshold ofthe server when the act of modifying at least one of the plurality ofconstituent power settings is performed.
 5. The method of claim 4,further comprising comparing the maximum power consumption threshold toa power consumption measurement at the current SPP-state and reducing atleast one of the plurality of constituent power settings associated withthe current SPP-state if the maximum power consumption threshold is lessthan the power consumption measurement at the current SPP-state.
 6. Themethod of claim 5, wherein the amount that the at least one of theplurality of constituent power settings is reduced by is less than apredetermined threshold.
 7. The method of claim 1, further comprisingreallocating power reductions to at least one other server.
 8. Themethod of claim 1, wherein the plurality of constituent power settingsincludes a p-state and power reduction of one or more server subsystemsother than the CPU.
 9. The method of claim 1, wherein the method isexecuted by a management processor.
 10. The method of claim 1, whereinat least some of the method is executed by a zone manager.
 11. A servercomprising: a central processing unit (CPU); a management processorcoupled to the CPU via a bus, wherein the management processor adjustspower consumption according to executable code, the code comprising amethod that further comprises: initializing the server to a system powerperformance state (SPP-state) that comprises a plurality of constituentpower settings contained in a table; determining whether powerregulation is required while the server is executing user applications;and modifying at least one of the plurality of constituent powersettings stored in the table.
 12. The server of claim 11, wherein thebus is a PCI bus.
 13. The server of claim 11, wherein the SPP-statecorresponds to a maximum power consumption measurement of the server andthe code further comprises resetting the maximum power consumptionmeasurement of the server when the act of increasing at least one of theplurality of constituent power settings is performed.
 14. The server ofclaim 13, wherein the code further comprises comparing the maximum powerconsumption measurement to the power consumption at the currentSPP-state and changing a power consumption value in the table for thecurrent SPP-state if the maximum power consumption measurement isgreater than the power consumption for the current SPP-state.
 15. Theserver of claim 14, wherein the amount that the at least one of theplurality of constituent power settings is reduced by is less than apredetermined threshold.
 16. The server of claim 15, the code furthercomprising reallocating power reductions to at least one other serverthat is coupled to the management processor.
 17. The server of claim 16,wherein at least some of the code is executed by a zone manager.
 18. Theserver of claim 11, wherein the management processor further couples toa second management processor that controls the power consumption for atleast one other server.
 19. A server comprising: a central processingunit (CPU); a means for managing power within a server coupled to theCPU, the means for managing power executing code, the code comprises amethod that further comprises: initializing the server to a system powerperformance state (SPP-state) that comprises a plurality of constituentpower settings contained in a table; determining whether powerregulation is required while the server is executing user applications;and modifying at least one of the plurality of constituent powersettings stored in the table.
 20. The server of claim 19, wherein themeans for managing power further couples to an additional means formanaging power that controls the power consumption for at least oneother server.